KR20060058020A - Lens of variable focal length - Google Patents

Abstract

The invention relates to a lens (10) of variable focal length comprising two transparent windows (24, 38) at least partially facing each other and parallel to one another and delimiting, at least in part, an internal volume (15) containing two non-miscible liquids, with different optical indices. The lens comprises an elastic means (36) capable of deforming in response to a change in pressure of the liquids in order to maintain the parallelism of the two transparent windows.

Description

Variable focal length lens {LENS OF VARIABLE FOCAL LENGTH}

1 is a cross-sectional view already described through a conventional exemplary embodiment of a variable focal length lens.

2 and 3 are cross-sectional views through exemplary embodiments of variable focal length lenses in accordance with the present invention in two successive steps in the lens manufacturing method.

4 is a cross sectional view through a further embodiment of a lens according to the invention;

5 shows a configuration of a mobile telephone including an optical device having a variable focal length lens in accordance with the present invention.

<Explanation of symbols for the main parts of the drawings>

10: Mount 16: Lens for Body

20, 34: side wall portion 23: wave portion

30: cap 24: 38: transparent cylindrical plate

36: elastic portion 42: middle portion

50: gasket 52: torus portion

54: skirt portion 56: crimped end

FIELD OF THE INVENTION The present invention relates to variable focal length lenses, and more particularly to such lenses utilizing the deformation of liquid droplets through electrowetting phenomena.

Various embodiments of variable focal length lenses are described in European patent 1 166 157 in the name of the applicant. Figure 1 of the present application essentially shows Figure 12 of that patent. The cell is defined by two transparent insulating plates 1 and 2 and side walls (not shown). The non-flat bottom plate 2 comprises a conical or cylindrical depression or recess 3 of the axis Δ comprising an insulating liquid drop 4. The remainder of the cell is filled with the electrically conductive liquid 5, which cannot be mixed with the insulating liquid and has different refractive indices and essentially the same density. An open annular electrode 7 in contact with the recess 3 is located on the rear part of the bottom plate 2. The other electrode 8 is in contact with the conductive liquid 5. Through the electrowetting phenomenon, it is possible to modify the curvature of the interface between the two liquids according to the voltage V applied between the electrodes 7 and 8, which curvature is indicated by reference numeral A for example. It changes from the initial concave shape to the convex shape indicated by the dotted line (B). Thus, the light beam passing through the cells perpendicular to the plates 1 and 2 in the droplet 4 region will be focused to a greater or lesser extent depending on the applied voltage. The conducting liquid is generally an aqueous solution, an insulating liquid or an oily liquid.

The mount for the lens formed of the transparent plates 1, 2 and the side walls connected to the transparent plate is generally of a rigid structure. The liquid pressure in the lens mount increases, for example, during the operation of assembling the parts constituting the mount, or once the mount is assembled, the liquid temperature of the lens with an expansion coefficient higher than the expansion coefficient of the material from which the mount is made increases. May increase substantially.

The excess of the pressure of the liquid contained in the lens carries the risk of causing deformation of the upper and lower transparent plates 1, 2, which in turn leads to undesirable light distortion. At worst, if the liquid pressure increase is too large, the transparent plates 1, 2 will be broken. Therefore, special measures need to be taken when assembling the lenses and / or it is necessary to define an acceptable temperature range for the storage and use of such lenses.

The present invention relates to a variable focal length lens, wherein the optical properties of the lens are not hindered during assembly and use of the lens by variations in the liquid pressure contained within the lens.

The invention also relates to a method of manufacturing such a variable focal length lens.

To achieve this object, the present invention provides a variable focal length lens having an optical axis Δ according to a first aspect, wherein the lens comprises two transparent windows, the transparent windows facing at least partially from each other. Reports an internal volume that includes two unmixed liquids that are parallel to each other and have different optical indices, define an interface, and the lens is elastically deformable in response to changes in liquid pressure Means;

According to a further aspect, the present invention provides a method of manufacturing a variable focal length lens comprising two transparent plates, the method comprising:

Positioning the transparent plates such that the transparent plates at least partially define an internal volume comprising two immiscible liquids having different optical indices, the two transparent plates facing each other at least partially A positioning step, parallel to each other;

Providing elastic means designed to deform in response to changes in liquid pressure to maintain parallelism of the two transparent plates

Include.

These objects, such features and advantages of the present invention will be described in detail in the following description of specific exemplary embodiments, given without being limited in connection with the accompanying drawings in conjunction with others.

According to one embodiment of the invention, there is preferably provided a lens structure having elastic means capable of deforming in response to variations in liquid pressure contained in the lens, and such deformation has little effect on the optical properties of the lens or It has no effect at all. Thus, any modification of the components that contribute to the optical properties of the lens is limited, thereby ensuring that the lens maintains the optical properties when the lens mount is assembled and the lens is used.

2 shows an exemplary embodiment of a mount for a variable focal length lens in accordance with the present invention at an intermediate stage in the mount manufacturing method. According to the invention the mount 10 for variable focal length lens consists of an upper part 12 and a lower part 14, which parts are made separately from each other and, when assembled, are insulated and conductive (not shown). Define an interior volume 15 comprising: The lower part 14 comprises a body 16 which is rotationally symmetric about an axis Δ made of steel, for example, and a base 17, through which the center passes through the central opening 18 and is at right angles. Continued by the cylindrical side 20 ending at the quadrilateral rim 22. The base 17 of the body 16 has a wavy portion 23 exhibiting rotational symmetry about the axis Δ and having a planar cross section including the axis Δ having an “S” shape. Include. A cylindrical plate 24 of transparent material, for example glass, is secured to the body 16, which body 16 is secured by the fixing material 22, for example weld glass or any other type of adhesive. The opening 18 on the same plane as the internal volume 15 of the mount 10 is covered.

The upper portion 12 of the mount 10 includes a cap 30, the cylindrical opening 32 passes through the center of the cap 30, extends by a cylindrical side wall portion 34, and the side wall The diameter of the part is larger than the diameter of the cylindrical wall 20 of the body 16. The cap 30 includes an elastic 36 provided between the opening 32 and the cylindrical side wall 34.

In the embodiment of FIG. 2, the plastic part 36 is composed of wave portions exhibiting rotational symmetry about the axis Δ, and the planar cross section including the axis Δ has a “S” shape.

Advantageously, the cap comprises an upper wall 31 connected to the transparent plate, and a cylindrical side wall 34, the upper wall comprising a bent portion 36 which is rotationally symmetric about the optical axis Δ of the lens. do. For example, the cap is made of stamped metal, for example stainless steel. The thickness of the top wall of the cap will depend on the predicted volume variation to compensate for the expansion effect of the liquid. For example, a typical thickness of about 0.1 to 0.25 mm showed good results for lenses with an outer diameter of less than 20 mm.

A cylindrical plate 38 made of a transparent material, for example glass, is fixed to the cap 30, which cap 30 is internal volume of the mount 10 by means of a fixing material 40, for example glass or adhesive. The opening part 32 on the same surface as 15 is covered.

The cylindrical plate 38 is used as a window for covering the opening 32. According to a variant of the invention, the window may be a fixed lens made of a transparent optical material.

The intermediate portion 42 is located at the base 17 of the body 16 on the same face as the inner volume 15. The middle portion 42 includes a planar surface 44 that lies against the glass plate 24, through which the opening 46 defines a conical surface 48 adjacent to the glass plate 24. The intermediate portion 42 is made of stainless steel, for example, and is covered with at least a planar insulating layer in contact with the conductive liquid contained in the mount 10. While using the lens, the edge of the interface between the conducting liquid and the insulating liquid contained in the inner volume 15 all moves along the quadrilateral surface 48, and the insulating liquid wets the glass plate 24. Advantageously, the roughness of the conical surface 48 is defined by a roughness parameter Ra (arithmetic mean deviation) of less than 0.1 μm for good control through the movement of the interface between the two liquids. To obtain such roughness values, the fabrication of the conical surface 48 may involve surface-finishing processes of abrasion polishing (friction polishing), electrolytic polishing or diamond-point processing type.

Gasket 50 is located between body 16 and cap 30 at the periphery of body 16 and cap 30. Gasket 50 includes toric portion 52 extending through skirt portion 54. For example, the gasket 50 consists of FKM, a standardized term for fluorosilicone or ethylene propylene diene (EPDM) terpolymers, or non-tonic fluorine polymers, wherein the torsion is Dupont Dow Elastomers. ) Is a brand name. More generally, the material from which the gasket 50 is made has a low absorption for the liquid contained in the internal volume 15 of the mount 10, which also contributes to the maintenance of the dielectric properties of the lens.

The manufacture of the lens mount 10 according to the invention starts with the separate manufacture of the upper part 12 and the lower part 14. The middle portion 42 is fixed to the body 16, for example, as a crimped fitting to obtain good electrical contact between the middle portion 42 and the body 16. Moreover, a sealing means is provided between the intermediate portion 42 and the glass plate 24. This involves the early deposition of a polymer layer, for example a curing adhesive, on the flat face 44 of the middle portion 42 or the glass plate 24. The gasket 50 is located in the body 16, the toric portion 52 lies in the middle portion 42, and the skirt portion 54 surrounds the cylindrical side wall 20 of the body 16. The quadrilateral rim 22 of the body 16 helps to hold the gasket 50 on the body 16 before the cap 30 is installed. The second portion 14 associated with the gasket 50 is then immersed in the conducting liquid. The droplet of insulation is in contact with the glass plate 24 and the conical surface 48. The placement of the insulating liquid may be facilitated by providing a layer of material that, at the surface of the glass plate 24 intended to be in contact with the insulating liquid, tends to preferentially wet with the insulating liquid rather than the conductive liquid. The cap 30 is then located in the gasket 50, and the skirt portion 54 of the gasket 50 is between the side wall portion 34 of the cap 30 and the side wall portion 20 of the body 16. Is inserted. At that time, this results in somewhat the lens mount 10 shown in FIG. Positioning the upper portion 12 on the lower portion 14 is advantageously performed in a liquid environment to limit the risk of air entering the internal volume 15 of the mount 10.

In the embodiment of FIG. 2, the portion 52 of the gasket compressed between the cap and the intermediate portion 42 is a torus, although other forms are possible for that portion 42. For example, the section of this portion of the gasket can be rectangular or any other shape.

The final step in the manufacture of the mount 10 is to intermediate the cap 30 with the crimping of the free rim of the side wall 34 of the cap 30 onto the body 16. Compressing the toric portion 52 of the gasket 50 between the portions 42 entails. By way of example, the cap 30 is crimped on the body 16 by controlling the compressive force applied on the gasket 50. This in turn results in the structure shown in FIG. 3 in which the side portion 34 of the cap 30 includes an end 56 crimped on the body 16. Therefore, the skirt portion 54 of the gasket 50 is compressed between the side wall portion 34 of the cap 30 and the side wall portion 20 of the body 16. Therefore, the sealing of the internal volume 15 of the mount 10 is provided by the compression of the torus 52 and the compression of the skirt portion 54 of the gasket 50.

Compared to the structure shown in FIG. 1, the upper electrode of the lens consists of a cap 30, and the lower electrode consists of a body 16 in electrical contact with the middle portion 42. Therefore, the gasket 50 also provides electrical insulation of the cap 30 with respect to the body 16.

According to this exemplary embodiment of the lens mount 10 according to the invention, the above-mentioned elastic means corresponds to the elastic part 36 of the cap 30. In particular, when the pressure in the internal volume 15 of the mount 10 rises, the elastic portion 36 provided on the cap 30 deforms preferentially relative to the other parts of the mount 10. Therefore, the stress exerted on the transparent cylindrical plates 24, 38 is reduced, so that any risk that the plates 24, 38 deform or rupture is avoided. Since the plates 24 and 38 are not deformed, the light output of the lens remains constant. Therefore, there is no variation in the focal length of the lens.

Since the elastic portion 36 is deformed, there may be some relative displacement of the transparent plate 36 relative to the transparent plate 24. However, given the rotational symmetry of the elastic part 36, such displacement of the transparent plate 38 occurs essentially alone along the axis Δ. Therefore, parallelism of the two transparent plates 24 and 38 is maintained, so that any deviation in the optical axis of the lens is avoided.

The wavy part 23 provided in the body 16 can also serve as an elastic means, but when the thickness of the body 16 exceeds the thickness of the cap 30, to a lesser extent than the elastic part 36. Will act as elastic means. However, the wave 23 may be deformed, for example, in case of significant expansion of the liquid contained in the mount 10.

According to a variant of the invention, the elastic means is formed, for example, in the intermediate portion 42 and from the internal volume 15 of the mount 10 comprising an insulating liquid and a conductive liquid by means of an impermeable membrane and an elastic membrane. It consists of a separate air-filling cavity. At this time, a change in pressure in the inner volume 15 causes deformation of the membrane.

According to another variant of the invention, the wetting of the conducting liquid, provided on the sealing layer provided between the glass plate 24 and the intermediate portion 42, and on the glass plate 24 on the same side as the inner volume 15. Compared with), the layer which promotes wetting with the insulating liquid is the same layer.

According to another variant of the invention, the material which fixes the glass plate to the cap 30 and the body 16, respectively, is protected by a protective layer, so that it is fixed in front of the liquid contained in the internal volume 15 of the mount 10. It does not deteriorate the means. This involves, for example, a protective layer composed mainly of organic materials.

According to another variant of the invention, once the intermediate portion 42 has been fixed to the body 16 in contact with the transparent plate 24, the whole is insulated on a surface designed to abut the internal volume 15 of the mount 10. Covered with layers

According to another variant of the invention, the intermediate portion 42 and the body 16 form a single portion to which the cap 30 is crimped. This single portion may include a shoulder that houses the transparent plate 24.

4 shows a section of a further embodiment of a lens according to the invention. According to this embodiment, and similarly the embodiment described in FIGS. 2 and 3, the lens 10 according to the invention comprises transparent windows 24, 38, which transparent windows face each other and are parallel to each other. High and at least partially defines an internal volume 15 comprising two immiscible liquids having different optical indices and an optical interface (not shown in FIG. 4). In FIG. 4, the window is a transparent plate made of an optically transparent material, for example glass. Depending on the variant, at least one of the windows may be a fixed optical length centered on the optical axis Δ of the variable focus lens.

As described above with reference to FIGS. 2 and 3, the lens includes a cap 30 connected to one of the transparent windows 38 and including a first cylindrical side wall portion 34. The lens also includes a body 16 with rotational symmetry, the axis of rotation defining the optical axis Δ of the lens. The body is connected to the other of the transparent windows 24 and includes a second cylindrical side wall portion 20 having a diameter smaller than the diameter of the first cylindrical wall portion. As before, the upper electrode consists of a cap 30 and the lower electrode consists of a body 16. The gasket 50 is provided to ensure the tightness of the lens mount. The gasket is compressed between the first and second cylindrical side wall portions. In the embodiment of FIG. 4, the gasket includes a skirt portion 54 compressed between the first and second cylindrical side wall portions, and a compressed portion 52 between the cap and the middle portion 42, in this example. It forms a single part with a body and includes an opening defining a conical or cylindrical surface through which the interface between the two liquids can move. According to the invention, the lens further comprises elastic means 36 which can deform in response to a change in the pressure of the liquid. In this embodiment, the elastic means comprises a bent portion 36 formed on the upper wall 31 of the cap, which is rotationally symmetric about the optical axis Δ of the lens. For example, the bent portion includes at least one circular bend centered on the optical axis Δ of the lens. In this example, the cap can also be made of stamping metal, for example in stainless steel. The thickness of the top wall of the cap will depend on the predicted volume variation to compensate for the expansion effect of the liquid. For example, a typical thickness of about 0.1 to 0.25 mm showed good results for lenses with an outer diameter of less than 20 mm.

Other elastic means may be provided. For example, an air-filled cavity can be inserted into the lens to compensate for the expansion effect of the liquid. In FIG. 4, the first side wall 34 includes a rim 56 crimped onto the body 16 for sealing of the cap onto the body. Other methods for sealing the cap on the body are possible, for example the cap can be glued onto the body.

As described in FIG. 4, the method of manufacturing a lens according to the present invention may be similar to the method described above.

Advantageously, the method comprises providing the cap 30 and the body 16 separately, wherein the windows 38 and 24 are sealed to the cap and the body. The gasket 50 is then positioned between the first and second cylindrical side wall portions, and the cap is positioned and sealed on the body after the inner volume is filled with two liquids.

According to a variant, the filling of the inner volume comprises dipping the body and the transparent window connected to the body in a solution of the conductive liquid, positioning the droplet of insulation in contact with the transparent window, positioning the gasket and the side wall of the cap. And the body remains immersed in the conducting liquid. Advantageously, sealing the side wall of the cap onto the body is carried out with the body still immersed in the conducting liquid to avoid introducing any air bubbles into the lens.

Due to the elastic means provided in the lens, no deformation of the window occurs, which can result from an increase in the pressure of the liquid during the manufacture of the lens.

Advantageously, as shown in FIG. 4, a cap is provided and the bent portion is rotationally symmetric about an axis Δ to carry out the inertia means.

Depending on the deformation, an air-filled cavity that can deform in response to a change in liquid pressure is inserted into the lens during manufacture of the lens.

Advantageously, sealing of the cap onto the body is carried out by crimping the side wall of the cap onto the body in order to obtain a very good mechanical strength of the mount.

Of course, the present invention can be changed and modified in various ways apparent to those skilled in the art. In particular, the aforementioned method steps may be modified. As an example, the introduction of the droplet of insulating liquid in the lower portion 14 of the mount 10 may be performed before the mount is immersed in the conductive liquid.

5 shows a configuration of an example of an optical device 60 incorporating a variable focal length lens 10 in accordance with the present invention. According to this example, the optical device includes a mount 61 holding a variable focal length 10 and a group 62 of fixed lenses. The optical device further comprises a driver 64 for driving the lens, which is connected to the electrodes of the lens via connections 65, 66.

Optical devices can be incorporated into many systems that require small variable focal length optical devices such as, for example, mobile phones, endoscope systems, and the like.

As described above, the present invention relates to a variable focal length lens, and more particularly, is effective for such a lens and the like that uses deformation of liquid droplets through an electrowetting phenomenon.

Claims (30)

As the variable focal length lens 10 having the optical axis Δ, An interior comprising two immiscible liquids having two different transparent windows 24, 38, at least partially facing each other and parallel to each other, at least in part, having different optical indices defining the interface A variable focal length lens with an optical axis, defining a volume (15), wherein the lens comprises elastic means (36) capable of deforming in response to a change in pressure of the liquid. 2. A variable focal length lens according to claim 1, wherein said elastic means is rotationally symmetric about an optical axis (Δ) of said lens. 3. A wall according to claim 2, comprising a wall portion (30) surrounding one of said transparent windows (38) and partially defining said inner volume (15), said wall portion being rotated about an optical axis (Δ) of said lens. A variable focal length lens with an optical axis, comprising a curved portion 36 that is symmetrical. 4. A variable focal length lens according to claim 3, wherein the curved portion (36) comprises at least one circular bend centered on the optical axis (Δ) of the lens. The method of claim 1, A cap 30 connected to one of said transparent windows; A body (16) connected to the other (24) of said transparent window; An intermediate portion 42 connected to the body or forming a single portion with the body, comprising an opening defining an adjacent conical or cylindrical surface 48 through which the interface between the two liquids can move. Part 42 And a variable focal length lens having an optical axis. 6. The cap 30 according to claim 5, wherein the cap 30 comprises a first cylindrical side wall portion 34, and the body 16 is of a second cylindrical side wall portion 20 having a diameter smaller than the diameter of the first cylindrical wall portion. Wherein the lens includes a gasket 50 having a first portion 52 compressed between the gap and the intermediate portion, and a skirt portion 54 compressed between the first and second cylindrical side wall portions. And a variable focal length lens having an optical axis. 7. A variable focal length lens with an optical axis according to claim 6, wherein the first portion compressed between the cap and the intermediate portion is toric. The method of claim 1, A cap 30 connected to one of said transparent windows and comprising a first cylindrical side wall; A second cylindrical side wall portion of rotationally symmetric about an axis Δ defining the optical axis of the lens, connected to the other one of the transparent windows 24 and having a diameter smaller than the diameter of the first cylindrical wall portion ( A body 16, including 20; A gasket 50 compressed between the first and second cylindrical side walls And a variable focal length lens having an optical axis. 9. The cap according to claim 8, wherein said cap comprises an upper wall portion (31) connected to said transparent window and extended by said first cylindrical side wall portion, said elastic means being about an optical axis (Δ) of said lens. And a bent portion (36) formed on the upper wall portion of the cap that is rotationally symmetric. 10. A variable focal length lens according to claim 9, wherein the bent portion includes at least one circular bend centered on the optical axis (Δ) of the lens. 10. The variable focal length lens of claim 9, wherein the cap is made of a stamped metal. The variable focal length lens of claim 11, wherein the thickness of the upper wall portion of the cap is about 0.1 to 0.25 mm. 9. An opening according to claim 8, defining an intermediate portion (42) connected to or forming a single portion with said body and an adjacent conical or conical surface (48) through which the interface between the two liquids can move. The variable focal length lens having an optical axis. 14. A variable focal length lens with an optical axis according to claim 5 or 13, wherein the surface has a roughness defined by a roughness parameter Ra of less than 0.1 [mu] m. The variable focal length with an optical axis according to claim 6, wherein the first side wall portion 34 comprises a rim 56 crimped on the body 16. lens. 14. Variable focus with an optical axis according to claim 5 or 13, comprising a sealing layer between the intermediate portion 42 and the associated transparent window 24 and / or between the body 16 and the transparent window. Length lens. 9. The associated transparent window (24) according to claim 5 or 8, wherein the body (16) and / or the cap (30) are covered by welding glass (22, 40) covered with a protective layer of organic compound as the main material. Variable focal length lens with an optical axis, which is connected to 38). 2. A variable focal length lens according to claim 1, wherein the window (24, 38) is a transparent plate. The variable focal length lens of claim 1, wherein at least one of the windows is a fixed lens. An optical device comprising a variable focal length lens according to claim 1. A mobile telephone comprising the optical device according to claim 20. A method of manufacturing a variable focal length lens having an optical axis DELTA, wherein the lens comprises two transparent windows, the transparent windows at least partially opposing and parallel to each other and at least partially different optical indexes. Defining an interior volume 15 comprising an immiscible conducting liquid and an insulating liquid, defining an interface, the lens further comprising elastic means 36 capable of deforming in response to a change in pressure of the liquid. In the method of manufacturing a variable focal length lens having an optical axis, Providing a cap 30 which is rotationally symmetric about an axis Δ, wherein a cylindrical opening passes through the center of the cap and is extended by a first cylindrical side wall, one of the transparent windows Providing a cap, the cap being sealed to cover the cap; Providing a body 16, wherein a second cylindrical opening passes through the central portion of the body and is extended by a second cylindrical side wall portion 20 having a diameter smaller than the diameter of the first cylindrical wall portion, and Providing a body, wherein the other transparent window is sealed to the body to cover the opening; Positioning a gasket between said first and second cylindrical side wall portions; Positioning and capping the cap on the body after the inner volume is filled with two liquids And a variable focal length lens having an optical axis. The method of claim 22, Positioning, in said body, an intermediate portion (42) comprising an opening defining a conical or cylindrical surface into which said interface can move. The method of claim 22, wherein the filling of the internal volume, Dipping the body and a transparent window connected to the body in a solution of the conductive liquid; Positioning an droplet of insulating liquid in contact with said transparent window; Positioning the side wall of the gasket and the cap, wherein the body remains immersed in the conductive liquid. And a variable focal length lens having an optical axis. 25. The method of claim 24, wherein sealing the side wall portion of the cap to the body is performed while the body remains immersed in the conductive liquid. 23. The method of claim 22, wherein the cap is provided with a bent portion that is rotationally symmetric about the axis Δ to perform the elastic means. 27. The method of claim 26, wherein the cap is made of stamping metal. 23. The method of claim 22, wherein sealing the cap to the body is performed by crimping the side wall portion of the cap onto the body. As a method of manufacturing a variable focal length lens (10) comprising two transparent plates (24, 38), Positioning the transparent plate such that the transparent plate at least partially defines an internal volume 15 comprising two immiscible liquids having different optical indices, the two transparent plates at least partially facing each other. Positioning the transparent plates parallel to each other; Providing an elastic means 36 designed to deform in response to a change in pressure of the liquid to keep the two transparent plates parallel Comprising a variable focal length lens. The method of claim 29, Providing a cap (30) connected to one (38) of said transparent plates and comprising a first cylindrical side wall portion (34); Providing a body (16) connected to the other (24) of said transparent plates and comprising a second cylindrical side wall portion (20) of diameter smaller than the diameter of said first cylindrical wall portion; Positioning an intermediate portion (42) in the body comprising a conical opening (48) through which the interface between the two liquids can move; On a body having a cross section of a gasket 50 comprising a torus portion 52 compressed between the cap and the intermediate portion and a skirt portion 54 compressed between the first and second cylindrical side wall portions. Crimping the cap on Further comprising, a method of manufacturing a variable focal length lens.

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